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f5abd8a616
The macro BIT_MASK is already defined in include/linux/bitops.h. To avoid name collisions rename BIT_MASK() in drivers/ram/k3-j721e/lpddr4_private.h to LPDDR4_BIT_MASK(). Remove superfluous parantheses. Remove superfluous comparison to 0. Signed-off-by: Heinrich Schuchardt <xypron.glpk@gmx.de> Reviewed-by: Simon Glass <sjg@chromium.org>
2105 lines
61 KiB
C
2105 lines
61 KiB
C
// SPDX-License-Identifier: BSD-3-Clause
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/******************************************************************************
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* Copyright (C) 2012-2018 Cadence Design Systems, Inc.
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* Copyright (C) 2019 Texas Instruments Incorporated - http://www.ti.com/
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*
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* lpddr4.c
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*
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*****************************************************************************
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*/
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#include "cps_drv_lpddr4.h"
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#include "lpddr4_ctl_regs.h"
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#include "lpddr4_if.h"
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#include "lpddr4_private.h"
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#include "lpddr4_sanity.h"
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#include "lpddr4_structs_if.h"
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#define LPDDR4_CUSTOM_TIMEOUT_DELAY 100000000U
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/**
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* Internal Function:Poll for status of interrupt received by the Controller.
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* @param[in] pD Driver state info specific to this instance.
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* @param[in] irqBit Interrupt status bit to be checked.
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* @param[in] delay time delay.
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* @return CDN_EOK on success (Interrupt status high).
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* @return EIO on poll time out.
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* @return EINVAL checking status was not successful.
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*/
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static uint32_t lpddr4_pollctlirq(const lpddr4_privatedata * pd,
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lpddr4_ctlinterrupt irqbit, uint32_t delay)
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{
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uint32_t result = 0U;
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uint32_t timeout = 0U;
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bool irqstatus = false;
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/* Loop until irqStatus found to be 1 or if value of 'result' !=CDN_EOK */
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do {
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if (++timeout == delay) {
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result = EIO;
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break;
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}
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/* cps_delayns(10000000U); */
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result = lpddr4_checkctlinterrupt(pd, irqbit, &irqstatus);
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} while ((irqstatus == false) && (result == (uint32_t) CDN_EOK));
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return result;
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}
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/**
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* Internal Function:Poll for status of interrupt received by the PHY Independent Module.
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* @param[in] pD Driver state info specific to this instance.
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* @param[in] irqBit Interrupt status bit to be checked.
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* @param[in] delay time delay.
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* @return CDN_EOK on success (Interrupt status high).
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* @return EIO on poll time out.
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* @return EINVAL checking status was not successful.
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*/
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static uint32_t lpddr4_pollphyindepirq(const lpddr4_privatedata * pd,
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lpddr4_phyindepinterrupt irqbit,
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uint32_t delay)
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{
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uint32_t result = 0U;
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uint32_t timeout = 0U;
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bool irqstatus = false;
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/* Loop until irqStatus found to be 1 or if value of 'result' !=CDN_EOK */
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do {
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if (++timeout == delay) {
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result = EIO;
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break;
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}
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/* cps_delayns(10000000U); */
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result = lpddr4_checkphyindepinterrupt(pd, irqbit, &irqstatus);
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} while ((irqstatus == false) && (result == (uint32_t) CDN_EOK));
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return result;
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}
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/**
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* Internal Function:Trigger function to poll and Ack IRQs
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* @param[in] pD Driver state info specific to this instance.
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* @return CDN_EOK on success (Interrupt status high).
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* @return EIO on poll time out.
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* @return EINVAL checking status was not successful.
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*/
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static uint32_t lpddr4_pollandackirq(const lpddr4_privatedata * pd)
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{
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uint32_t result = 0U;
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/* Wait for PhyIndependent module to finish up ctl init sequence */
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result =
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lpddr4_pollphyindepirq(pd, LPDDR4_PHY_INDEP_INIT_DONE_BIT,
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LPDDR4_CUSTOM_TIMEOUT_DELAY);
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/* Ack to clear the PhyIndependent interrupt bit */
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if (result == (uint32_t) CDN_EOK) {
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result =
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lpddr4_ackphyindepinterrupt(pd,
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LPDDR4_PHY_INDEP_INIT_DONE_BIT);
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}
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/* Wait for the CTL end of initialization */
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if (result == (uint32_t) CDN_EOK) {
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result =
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lpddr4_pollctlirq(pd, LPDDR4_MC_INIT_DONE,
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LPDDR4_CUSTOM_TIMEOUT_DELAY);
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}
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/* Ack to clear the Ctl interrupt bit */
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if (result == (uint32_t) CDN_EOK) {
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result = lpddr4_ackctlinterrupt(pd, LPDDR4_MC_INIT_DONE);
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}
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return result;
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}
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/**
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* Internal Function: Controller start sequence.
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* @param[in] pD Driver state info specific to this instance.
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* @return CDN_EOK on success.
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* @return EINVAL starting controller was not successful.
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*/
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static uint32_t lpddr4_startsequencecontroller(const lpddr4_privatedata * pd)
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{
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uint32_t result = 0U;
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uint32_t regval = 0U;
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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lpddr4_infotype infotype;
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/* Set the PI_start to initiate leveling procedure */
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regval =
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CPS_FLD_SET(LPDDR4__PI_START__FLD,
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CPS_REG_READ(&(ctlregbase->LPDDR4__PI_START__REG)));
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CPS_REG_WRITE((&(ctlregbase->LPDDR4__PI_START__REG)), regval);
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/* Set the Ctl_start */
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regval =
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CPS_FLD_SET(LPDDR4__START__FLD,
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CPS_REG_READ(&(ctlregbase->LPDDR4__START__REG)));
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CPS_REG_WRITE(&(ctlregbase->LPDDR4__START__REG), regval);
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if (pd->infohandler != NULL) {
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/* If a handler is registered, call it with the relevant information type */
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infotype = LPDDR4_DRV_SOC_PLL_UPDATE;
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pd->infohandler(pd, infotype);
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}
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result = lpddr4_pollandackirq(pd);
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return result;
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}
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/**
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* Internal Function: To add the offset to given address.
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* @param[in] addr Address to which the offset has to be added.
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* @param[in] regOffset The offset
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* @return regAddr The address value after the summation.
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*/
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static volatile uint32_t *lpddr4_addoffset(volatile uint32_t * addr,
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uint32_t regoffset)
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{
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volatile uint32_t *local_addr = addr;
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/* Declaring as array to add the offset value. */
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volatile uint32_t *regaddr = &local_addr[regoffset];
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return regaddr;
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}
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/**
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* Checks configuration object.
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* @param[in] config Driver/hardware configuration required.
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* @param[out] configSize Size of memory allocations required.
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* @return CDN_EOK on success (requirements structure filled).
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* @return ENOTSUP if configuration cannot be supported due to driver/hardware constraints.
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*/
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uint32_t lpddr4_probe(const lpddr4_config * config, uint16_t * configsize)
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{
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uint32_t result;
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result = (uint32_t) (lpddr4_probesf(config, configsize));
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if (result == (uint32_t) CDN_EOK) {
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*configsize = (uint16_t) (sizeof(lpddr4_privatedata));
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}
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return result;
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}
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/**
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* Init function to be called after LPDDR4_probe() to set up the driver configuration.
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* Memory should be allocated for drv_data (using the size determined using LPDDR4_probe) before
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* calling this API, init_settings should be initialized with base addresses for PHY Independent Module,
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* Controller and PHY before calling this function.
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* If callbacks are required for interrupt handling, these should also be configured in init_settings.
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* @param[in] pD Driver state info specific to this instance.
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* @param[in] cfg Specifies driver/hardware configuration.
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* @return CDN_EOK on success
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* @return EINVAL if illegal/inconsistent values in cfg.
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* @return ENOTSUP if hardware has an inconsistent configuration or doesn't support feature(s)
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* required by 'config' parameters.
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*/
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uint32_t lpddr4_init(lpddr4_privatedata * pd, const lpddr4_config * cfg)
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{
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uint32_t result = 0U;
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uint16_t productid = 0U;
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result = lpddr4_initsf(pd, cfg);
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if (result == (uint32_t) CDN_EOK) {
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/* Validate Magic number */
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) cfg->ctlbase;
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productid = (uint16_t) (CPS_FLD_READ(LPDDR4__CONTROLLER_ID__FLD,
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__CONTROLLER_ID__REG))));
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if (productid == PRODUCT_ID) {
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/* Populating configuration data to pD */
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pd->ctlbase = ctlregbase;
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pd->infohandler =
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(lpddr4_infocallback) cfg->infohandler;
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pd->ctlinterrupthandler =
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(lpddr4_ctlcallback) cfg->ctlinterrupthandler;
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pd->phyindepinterrupthandler =
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(lpddr4_phyindepcallback) cfg->
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phyindepinterrupthandler;
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} else {
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/* Magic number validation failed - Driver doesn't support given IP version */
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result = (uint32_t) EOPNOTSUPP;
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}
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}
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return result;
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}
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/**
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* Start the driver.
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* @param[in] pD Driver state info specific to this instance.
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*/
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uint32_t lpddr4_start(const lpddr4_privatedata * pd)
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{
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uint32_t result = 0U;
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uint32_t regval = 0U;
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result = lpddr4_startsf(pd);
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if (result == (uint32_t) CDN_EOK) {
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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/* Enable PI as the initiator for DRAM */
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regval =
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CPS_FLD_SET(LPDDR4__PI_INIT_LVL_EN__FLD,
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__PI_INIT_LVL_EN__REG)));
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regval = CPS_FLD_SET(LPDDR4__PI_NORMAL_LVL_SEQ__FLD, regval);
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CPS_REG_WRITE((&(ctlregbase->LPDDR4__PI_INIT_LVL_EN__REG)),
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regval);
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/* Start PI init sequence. */
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result = lpddr4_startsequencecontroller(pd);
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}
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return result;
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}
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/**
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* Read a register from the controller, PHY or PHY Independent Module
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* @param[in] pD Driver state info specific to this instance.
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* @param[in] cpp Indicates whether controller, PHY or PHY Independent Module register
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* @param[in] regOffset Register offset
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* @param[out] regValue Register value read
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* @return CDN_EOK on success.
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* @return EINVAL if regOffset if out of range or regValue is NULL
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*/
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uint32_t lpddr4_readreg(const lpddr4_privatedata * pd, lpddr4_regblock cpp,
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uint32_t regoffset, uint32_t * regvalue)
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{
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uint32_t result = 0U;
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result = lpddr4_readregsf(pd, cpp, regvalue);
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if (result == (uint32_t) CDN_EOK) {
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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if (cpp == LPDDR4_CTL_REGS) {
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if (regoffset >= LPDDR4_CTL_REG_COUNT) {
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/* Return if user provider invalid register number */
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result = EINVAL;
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} else {
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*regvalue =
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CPS_REG_READ(lpddr4_addoffset
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(&(ctlregbase->DENALI_CTL_0),
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regoffset));
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}
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} else if (cpp == LPDDR4_PHY_REGS) {
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if (regoffset >= LPDDR4_PHY_REG_COUNT) {
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/* Return if user provider invalid register number */
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result = EINVAL;
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} else {
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*regvalue =
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CPS_REG_READ(lpddr4_addoffset
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(&(ctlregbase->DENALI_PHY_0),
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regoffset));
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}
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} else {
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if (regoffset >= LPDDR4_PHY_INDEP_REG_COUNT) {
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/* Return if user provider invalid register number */
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result = EINVAL;
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} else {
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*regvalue =
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CPS_REG_READ(lpddr4_addoffset
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(&(ctlregbase->DENALI_PI_0),
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regoffset));
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}
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}
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}
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return result;
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}
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uint32_t lpddr4_writereg(const lpddr4_privatedata * pd, lpddr4_regblock cpp,
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uint32_t regoffset, uint32_t regvalue)
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{
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uint32_t result = 0U;
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result = lpddr4_writeregsf(pd, cpp);
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if (result == (uint32_t) CDN_EOK) {
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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if (cpp == LPDDR4_CTL_REGS) {
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if (regoffset >= LPDDR4_CTL_REG_COUNT) {
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/* Return if user provider invalid register number */
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result = EINVAL;
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} else {
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CPS_REG_WRITE(lpddr4_addoffset
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(&(ctlregbase->DENALI_CTL_0),
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regoffset), regvalue);
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}
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} else if (cpp == LPDDR4_PHY_REGS) {
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if (regoffset >= LPDDR4_PHY_REG_COUNT) {
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/* Return if user provider invalid register number */
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result = EINVAL;
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} else {
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CPS_REG_WRITE(lpddr4_addoffset
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(&(ctlregbase->DENALI_PHY_0),
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regoffset), regvalue);
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}
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} else {
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if (regoffset >= LPDDR4_PHY_INDEP_REG_COUNT) {
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/* Return if user provider invalid register number */
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result = EINVAL;
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} else {
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CPS_REG_WRITE(lpddr4_addoffset
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(&(ctlregbase->DENALI_PI_0),
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regoffset), regvalue);
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}
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}
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}
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return result;
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}
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static uint32_t lpddr4_checkmmrreaderror(const lpddr4_privatedata * pd,
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uint64_t * mmrvalue,
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uint8_t * mrrstatus)
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{
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uint64_t lowerdata;
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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uint32_t result = (uint32_t) CDN_EOK;
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/* Check if mode register read error interrupt occurred */
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if (lpddr4_pollctlirq(pd, LPDDR4_MRR_ERROR, 100) == 0U) {
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/* Mode register read error interrupt, read MRR status register and return. */
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*mrrstatus =
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(uint8_t) CPS_FLD_READ(LPDDR4__MRR_ERROR_STATUS__FLD,
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__MRR_ERROR_STATUS__REG)));
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*mmrvalue = 0;
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result = EIO;
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} else {
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*mrrstatus = 0;
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/* Mode register read was successful, read DATA */
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lowerdata =
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__PERIPHERAL_MRR_DATA_0__REG));
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*mmrvalue =
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__PERIPHERAL_MRR_DATA_1__REG));
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*mmrvalue = (uint64_t) ((*mmrvalue << WORD_SHIFT) | lowerdata);
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/* Acknowledge MR_READ_DONE interrupt to clear it */
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result = lpddr4_ackctlinterrupt(pd, LPDDR4_MR_READ_DONE);
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}
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return result;
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}
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uint32_t lpddr4_getmmrregister(const lpddr4_privatedata * pd,
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uint32_t readmoderegval, uint64_t * mmrvalue,
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uint8_t * mmrstatus)
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{
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uint32_t result = 0U;
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uint32_t tdelay = 1000U;
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uint32_t regval = 0U;
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result = lpddr4_getmmrregistersf(pd, mmrvalue, mmrstatus);
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if (result == (uint32_t) CDN_EOK) {
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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/* Populate the calculated value to the register */
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regval =
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CPS_FLD_WRITE(LPDDR4__READ_MODEREG__FLD,
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__READ_MODEREG__REG)),
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readmoderegval);
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CPS_REG_WRITE(&(ctlregbase->LPDDR4__READ_MODEREG__REG), regval);
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/* Wait until the Read is done */
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result = lpddr4_pollctlirq(pd, LPDDR4_MR_READ_DONE, tdelay);
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}
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if (result == (uint32_t) CDN_EOK) {
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result = lpddr4_checkmmrreaderror(pd, mmrvalue, mmrstatus);
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}
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return result;
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}
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static uint32_t lpddr4_writemmrregister(const lpddr4_privatedata * pd,
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uint32_t writemoderegval)
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{
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uint32_t result = (uint32_t) CDN_EOK;
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uint32_t tdelay = 1000U;
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uint32_t regval = 0U;
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lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
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/* Populate the calculated value to the register */
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regval =
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CPS_FLD_WRITE(LPDDR4__WRITE_MODEREG__FLD,
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CPS_REG_READ(&
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(ctlregbase->
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LPDDR4__WRITE_MODEREG__REG)),
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writemoderegval);
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CPS_REG_WRITE(&(ctlregbase->LPDDR4__WRITE_MODEREG__REG), regval);
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result = lpddr4_pollctlirq(pd, LPDDR4_MR_WRITE_DONE, tdelay);
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return result;
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}
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uint32_t lpddr4_setmmrregister(const lpddr4_privatedata * pd,
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uint32_t writemoderegval, uint8_t * mrwstatus)
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{
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uint32_t result = 0U;
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result = lpddr4_setmmrregistersf(pd, mrwstatus);
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if (result == (uint32_t) CDN_EOK) {
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/* Function call to trigger Mode register write */
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result = lpddr4_writemmrregister(pd, writemoderegval);
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if (result == (uint32_t) CDN_EOK) {
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result =
|
||
lpddr4_ackctlinterrupt(pd, LPDDR4_MR_WRITE_DONE);
|
||
}
|
||
/* Read the status of mode register write */
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase =
|
||
(lpddr4_ctlregs *) pd->ctlbase;
|
||
*mrwstatus =
|
||
(uint8_t) CPS_FLD_READ(LPDDR4__MRW_STATUS__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__MRW_STATUS__REG)));
|
||
if ((*mrwstatus) != 0U) {
|
||
result = EIO;
|
||
}
|
||
}
|
||
}
|
||
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_writectlconfig(const lpddr4_privatedata * pd,
|
||
const lpddr4_reginitdata * regvalues)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regnum;
|
||
|
||
result = lpddr4_writectlconfigsf(pd, regvalues);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
|
||
/* Iterate through CTL register numbers. */
|
||
for (regnum = 0; regnum < LPDDR4_CTL_REG_COUNT; regnum++) {
|
||
/* Check if the user has requested update */
|
||
if (regvalues->updatectlreg[regnum]) {
|
||
result =
|
||
lpddr4_writereg(pd, LPDDR4_CTL_REGS, regnum,
|
||
(uint32_t) (regvalues->
|
||
denalictlreg
|
||
[regnum]));
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_writephyindepconfig(const lpddr4_privatedata * pd,
|
||
const lpddr4_reginitdata * regvalues)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regnum;
|
||
|
||
result = lpddr4_writephyindepconfigsf(pd, regvalues);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
|
||
/* Iterate through PHY Independent module register numbers. */
|
||
for (regnum = 0; regnum < LPDDR4_PHY_INDEP_REG_COUNT; regnum++) {
|
||
/* Check if the user has requested update */
|
||
if (regvalues->updatephyindepreg[regnum]) {
|
||
result =
|
||
lpddr4_writereg(pd, LPDDR4_PHY_INDEP_REGS,
|
||
regnum,
|
||
(uint32_t) (regvalues->
|
||
denaliphyindepreg
|
||
[regnum]));
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_writephyconfig(const lpddr4_privatedata * pd,
|
||
const lpddr4_reginitdata * regvalues)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regnum;
|
||
|
||
result = lpddr4_writephyconfigsf(pd, regvalues);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
|
||
/* Iterate through PHY register numbers. */
|
||
for (regnum = 0; regnum < LPDDR4_PHY_REG_COUNT; regnum++) {
|
||
/* Check if the user has requested update */
|
||
if (regvalues->updatephyreg[regnum]) {
|
||
result =
|
||
lpddr4_writereg(pd, LPDDR4_PHY_REGS, regnum,
|
||
(uint32_t) (regvalues->
|
||
denaliphyreg
|
||
[regnum]));
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_readctlconfig(const lpddr4_privatedata * pd,
|
||
lpddr4_reginitdata * regvalues)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regnum;
|
||
result = lpddr4_readctlconfigsf(pd, regvalues);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
/* Iterate through CTL register numbers. */
|
||
for (regnum = 0; regnum < LPDDR4_CTL_REG_COUNT; regnum++) {
|
||
/* Check if the user has requested read (updateCtlReg=1) */
|
||
if (regvalues->updatectlreg[regnum]) {
|
||
result =
|
||
lpddr4_readreg(pd, LPDDR4_CTL_REGS, regnum,
|
||
(uint32_t *) (®values->
|
||
denalictlreg
|
||
[regnum]));
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_readphyindepconfig(const lpddr4_privatedata * pd,
|
||
lpddr4_reginitdata * regvalues)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regnum;
|
||
|
||
result = lpddr4_readphyindepconfigsf(pd, regvalues);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
/* Iterate through PHY Independent module register numbers. */
|
||
for (regnum = 0; regnum < LPDDR4_PHY_INDEP_REG_COUNT; regnum++) {
|
||
/* Check if the user has requested read (updateCtlReg=1) */
|
||
if (regvalues->updatephyindepreg[regnum]) {
|
||
result =
|
||
lpddr4_readreg(pd, LPDDR4_PHY_INDEP_REGS,
|
||
regnum,
|
||
(uint32_t *) (®values->
|
||
denaliphyindepreg
|
||
[regnum]));
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_readphyconfig(const lpddr4_privatedata * pd,
|
||
lpddr4_reginitdata * regvalues)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regnum;
|
||
|
||
result = lpddr4_readphyconfigsf(pd, regvalues);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
/* Iterate through PHY register numbers. */
|
||
for (regnum = 0; regnum < LPDDR4_PHY_REG_COUNT; regnum++) {
|
||
/* Check if the user has requested read (updateCtlReg=1) */
|
||
if (regvalues->updatephyreg[regnum]) {
|
||
result =
|
||
lpddr4_readreg(pd, LPDDR4_PHY_REGS, regnum,
|
||
(uint32_t *) (®values->
|
||
denaliphyreg
|
||
[regnum]));
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_getctlinterruptmask(const lpddr4_privatedata * pd,
|
||
uint64_t * mask)
|
||
{
|
||
uint32_t result = 0U;
|
||
uint64_t lowermask = 0U;
|
||
|
||
result = lpddr4_getctlinterruptmasksf(pd, mask);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Reading the lower mask register */
|
||
lowermask =
|
||
(uint64_t) (CPS_FLD_READ
|
||
(LPDDR4__INT_MASK_0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__INT_MASK_0__REG))));
|
||
/* Reading the upper mask register */
|
||
*mask =
|
||
(uint64_t) (CPS_FLD_READ
|
||
(LPDDR4__INT_MASK_1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__INT_MASK_1__REG))));
|
||
/* Concatenate both register informations */
|
||
*mask = (uint64_t) ((*mask << WORD_SHIFT) | lowermask);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_setctlinterruptmask(const lpddr4_privatedata * pd,
|
||
const uint64_t * mask)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regval = 0;
|
||
const uint64_t ui64one = 1ULL;
|
||
const uint32_t ui32irqcount = (uint32_t) LPDDR4_LOR_BITS + 1U;
|
||
|
||
result = lpddr4_setctlinterruptmasksf(pd, mask);
|
||
if ((result == (uint32_t) CDN_EOK) && (ui32irqcount < 64U)) {
|
||
/* Return if the user given value is higher than the field width */
|
||
if (*mask >= (ui64one << ui32irqcount)) {
|
||
result = EINVAL;
|
||
}
|
||
}
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Extracting the lower 32 bits and writing to lower mask register */
|
||
regval = (uint32_t) (*mask & WORD_MASK);
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__INT_MASK_0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__INT_MASK_0__REG)),
|
||
regval);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__INT_MASK_0__REG), regval);
|
||
|
||
/* Extracting the upper 32 bits and writing to upper mask register */
|
||
regval = (uint32_t) ((*mask >> WORD_SHIFT) & WORD_MASK);
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__INT_MASK_1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__INT_MASK_1__REG)),
|
||
regval);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__INT_MASK_1__REG), regval);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_checkctlinterrupt(const lpddr4_privatedata * pd,
|
||
lpddr4_ctlinterrupt intr, bool * irqstatus)
|
||
{
|
||
uint32_t result;
|
||
uint32_t ctlirqstatus = 0;
|
||
uint32_t fieldshift = 0;
|
||
|
||
/* NOTE:This function assume irq status is mentioned in NOT more than 2 registers.
|
||
* Value of 'interrupt' should be less than 64 */
|
||
result = lpddr4_checkctlinterruptsf(pd, intr, irqstatus);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
if ((uint32_t) intr >= WORD_SHIFT) {
|
||
ctlirqstatus =
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__INT_STATUS_1__REG));
|
||
/* Reduce the shift value as we are considering upper register */
|
||
fieldshift = (uint32_t) intr - ((uint32_t) WORD_SHIFT);
|
||
} else {
|
||
ctlirqstatus =
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__INT_STATUS_0__REG));
|
||
/* The shift value remains same for lower interrupt register */
|
||
fieldshift = (uint32_t) intr;
|
||
}
|
||
|
||
/* MISRA compliance (Shifting operation) check */
|
||
if (fieldshift < WORD_SHIFT) {
|
||
if ((ctlirqstatus >> fieldshift) & LPDDR4_BIT_MASK) {
|
||
*irqstatus = true;
|
||
} else {
|
||
*irqstatus = false;
|
||
}
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_ackctlinterrupt(const lpddr4_privatedata * pd,
|
||
lpddr4_ctlinterrupt intr)
|
||
{
|
||
uint32_t result = 0;
|
||
uint32_t regval = 0;
|
||
uint32_t localinterrupt = (uint32_t) intr;
|
||
|
||
/* NOTE:This function assume irq status is mentioned in NOT more than 2 registers.
|
||
* Value of 'interrupt' should be less than 64 */
|
||
result = lpddr4_ackctlinterruptsf(pd, intr);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Check if the requested bit is in upper register */
|
||
if (localinterrupt > WORD_SHIFT) {
|
||
localinterrupt =
|
||
(localinterrupt - (uint32_t) WORD_SHIFT);
|
||
regval = (uint32_t)LPDDR4_BIT_MASK << localinterrupt;
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__INT_ACK_1__REG),
|
||
regval);
|
||
} else {
|
||
regval = (uint32_t)LPDDR4_BIT_MASK << localinterrupt;
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__INT_ACK_0__REG),
|
||
regval);
|
||
}
|
||
}
|
||
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_getphyindepinterruptmask(const lpddr4_privatedata * pd,
|
||
uint32_t * mask)
|
||
{
|
||
uint32_t result;
|
||
|
||
result = lpddr4_getphyindepinterruptmsf(pd, mask);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Reading mask register */
|
||
*mask =
|
||
CPS_FLD_READ(LPDDR4__PI_INT_MASK__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__PI_INT_MASK__REG)));
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_setphyindepinterruptmask(const lpddr4_privatedata * pd,
|
||
const uint32_t * mask)
|
||
{
|
||
uint32_t result;
|
||
uint32_t regval = 0;
|
||
const uint32_t ui32irqcount =
|
||
(uint32_t) LPDDR4_PHY_INDEP_DLL_LOCK_STATE_CHANGE_BIT + 1U;
|
||
|
||
result = lpddr4_setphyindepinterruptmsf(pd, mask);
|
||
if ((result == (uint32_t) CDN_EOK) && (ui32irqcount < WORD_SHIFT)) {
|
||
/* Return if the user given value is higher than the field width */
|
||
if (*mask >= (1U << ui32irqcount)) {
|
||
result = EINVAL;
|
||
}
|
||
}
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Writing to the user requested interrupt mask */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__PI_INT_MASK__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__PI_INT_MASK__REG)),
|
||
*mask);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__PI_INT_MASK__REG), regval);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_checkphyindepinterrupt(const lpddr4_privatedata * pd,
|
||
lpddr4_phyindepinterrupt intr,
|
||
bool * irqstatus)
|
||
{
|
||
uint32_t result = 0;
|
||
uint32_t phyindepirqstatus = 0;
|
||
|
||
result = lpddr4_checkphyindepinterrupsf(pd, intr, irqstatus);
|
||
/* Confirming that the value of interrupt is less than register width */
|
||
if ((result == (uint32_t) CDN_EOK) && ((uint32_t) intr < WORD_SHIFT)) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Reading the requested bit to check interrupt status */
|
||
phyindepirqstatus =
|
||
CPS_REG_READ(&(ctlregbase->LPDDR4__PI_INT_STATUS__REG));
|
||
*irqstatus =
|
||
!!((phyindepirqstatus >> (uint32_t)intr) & LPDDR4_BIT_MASK);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_ackphyindepinterrupt(const lpddr4_privatedata * pd,
|
||
lpddr4_phyindepinterrupt intr)
|
||
{
|
||
uint32_t result = 0U;
|
||
uint32_t regval = 0U;
|
||
uint32_t ui32shiftinterrupt = (uint32_t) intr;
|
||
|
||
result = lpddr4_ackphyindepinterruptsf(pd, intr);
|
||
/* Confirming that the value of interrupt is less than register width */
|
||
if ((result == (uint32_t) CDN_EOK) && (ui32shiftinterrupt < WORD_SHIFT)) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Write 1 to the requested bit to ACk the interrupt */
|
||
regval = (uint32_t)LPDDR4_BIT_MASK << ui32shiftinterrupt;
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__PI_INT_ACK__REG), regval);
|
||
}
|
||
|
||
return result;
|
||
}
|
||
|
||
/* Check for caTrainingError */
|
||
static void lpddr4_checkcatrainingerror(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo,
|
||
bool * errfoundptr)
|
||
{
|
||
|
||
uint32_t regval;
|
||
uint32_t errbitmask = 0U;
|
||
uint32_t snum;
|
||
volatile uint32_t *regaddress;
|
||
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__PHY_ADR_CALVL_OBS1_0__REG));
|
||
errbitmask = (CA_TRAIN_RL) | (NIBBLE_MASK);
|
||
/* PHY_ADR_CALVL_OBS1[4] – Right found
|
||
PHY_ADR_CALVL_OBS1[5] – left found
|
||
both the above fields should be high and below field should be zero.
|
||
PHY_ADR_CALVL_OBS1[3:0] – calvl_state
|
||
*/
|
||
for (snum = 0U; snum < ASLICE_NUM; snum++) {
|
||
regval = CPS_REG_READ(regaddress);
|
||
if ((regval & errbitmask) != CA_TRAIN_RL) {
|
||
debuginfo->catraingerror = true;
|
||
*errfoundptr = true;
|
||
}
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress, (uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
|
||
/* Check for wrLvlError */
|
||
static void lpddr4_checkwrlvlerror(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo,
|
||
bool * errfoundptr)
|
||
{
|
||
|
||
uint32_t regval;
|
||
uint32_t errbitmask = 0U;
|
||
uint32_t snum;
|
||
volatile uint32_t *regaddress;
|
||
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__PHY_WRLVL_ERROR_OBS_0__REG));
|
||
/* PHY_WRLVL_ERROR_OBS_X[1:0] should be zero */
|
||
errbitmask = (LPDDR4_BIT_MASK << 1) | LPDDR4_BIT_MASK;
|
||
for (snum = 0U; snum < DSLICE_NUM; snum++) {
|
||
regval = CPS_REG_READ(regaddress);
|
||
if ((regval & errbitmask) != 0U) {
|
||
debuginfo->wrlvlerror = true;
|
||
*errfoundptr = true;
|
||
}
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress, (uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
|
||
/* Check for GateLvlError */
|
||
static void lpddr4_checkgatelvlerror(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo,
|
||
bool * errfoundptr)
|
||
{
|
||
|
||
uint32_t regval;
|
||
uint32_t errbitmask = 0U;
|
||
uint32_t snum;
|
||
volatile uint32_t *regaddress;
|
||
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__PHY_GTLVL_STATUS_OBS_0__REG));
|
||
/* PHY_GTLVL_STATUS_OBS[6] – gate_level min error
|
||
* PHY_GTLVL_STATUS_OBS[7] – gate_level max error
|
||
* All the above bit fields should be zero */
|
||
errbitmask = GATE_LVL_ERROR_FIELDS;
|
||
for (snum = 0U; snum < DSLICE_NUM; snum++) {
|
||
regval = CPS_REG_READ(regaddress);
|
||
if ((regval & errbitmask) != 0U) {
|
||
debuginfo->gatelvlerror = true;
|
||
*errfoundptr = true;
|
||
}
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress, (uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
|
||
/* Check for ReadLvlError */
|
||
static void lpddr4_checkreadlvlerror(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo,
|
||
bool * errfoundptr)
|
||
{
|
||
|
||
uint32_t regval;
|
||
uint32_t errbitmask = 0U;
|
||
uint32_t snum;
|
||
volatile uint32_t *regaddress;
|
||
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__PHY_RDLVL_STATUS_OBS_0__REG));
|
||
/* PHY_RDLVL_STATUS_OBS[23:16] – failed bits : should be zero.
|
||
PHY_RDLVL_STATUS_OBS[31:28] – rdlvl_state : should be zero */
|
||
errbitmask = READ_LVL_ERROR_FIELDS;
|
||
for (snum = 0U; snum < DSLICE_NUM; snum++) {
|
||
regval = CPS_REG_READ(regaddress);
|
||
if ((regval & errbitmask) != 0U) {
|
||
debuginfo->readlvlerror = true;
|
||
*errfoundptr = true;
|
||
}
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress, (uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
|
||
/* Check for DqTrainingError */
|
||
static void lpddr4_checkdqtrainingerror(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo,
|
||
bool * errfoundptr)
|
||
{
|
||
|
||
uint32_t regval;
|
||
uint32_t errbitmask = 0U;
|
||
uint32_t snum;
|
||
volatile uint32_t *regaddress;
|
||
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__PHY_WDQLVL_STATUS_OBS_0__REG));
|
||
/* PHY_WDQLVL_STATUS_OBS[26:18] should all be zero. */
|
||
errbitmask = DQ_LVL_STATUS;
|
||
for (snum = 0U; snum < DSLICE_NUM; snum++) {
|
||
regval = CPS_REG_READ(regaddress);
|
||
if ((regval & errbitmask) != 0U) {
|
||
debuginfo->dqtrainingerror = true;
|
||
*errfoundptr = true;
|
||
}
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress, (uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
|
||
/**
|
||
* Internal Function:For checking errors in training/levelling sequence.
|
||
* @param[in] pD Driver state info specific to this instance.
|
||
* @param[in] debugInfo pointer to debug information.
|
||
* @param[out] errFoundPtr pointer to return if error found.
|
||
* @return CDN_EOK on success (Interrupt status high).
|
||
* @return EINVAL checking or unmasking was not successful.
|
||
*/
|
||
static bool lpddr4_checklvlerrors(const lpddr4_privatedata * pd,
|
||
lpddr4_debuginfo * debuginfo, bool errfound)
|
||
{
|
||
|
||
bool localerrfound = errfound;
|
||
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
if (localerrfound == false) {
|
||
/* Check for ca training error */
|
||
lpddr4_checkcatrainingerror(ctlregbase, debuginfo,
|
||
&localerrfound);
|
||
}
|
||
|
||
if (localerrfound == false) {
|
||
/* Check for Write leveling error */
|
||
lpddr4_checkwrlvlerror(ctlregbase, debuginfo, &localerrfound);
|
||
}
|
||
|
||
if (localerrfound == false) {
|
||
/* Check for Gate leveling error */
|
||
lpddr4_checkgatelvlerror(ctlregbase, debuginfo, &localerrfound);
|
||
}
|
||
|
||
if (localerrfound == false) {
|
||
/* Check for Read leveling error */
|
||
lpddr4_checkreadlvlerror(ctlregbase, debuginfo, &localerrfound);
|
||
}
|
||
|
||
if (localerrfound == false) {
|
||
/* Check for DQ training error */
|
||
lpddr4_checkdqtrainingerror(ctlregbase, debuginfo,
|
||
&localerrfound);
|
||
}
|
||
return localerrfound;
|
||
}
|
||
|
||
static bool lpddr4_seterror(volatile uint32_t * reg, uint32_t errbitmask,
|
||
bool * errfoundptr, const uint32_t errorinfobits)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
|
||
/* Read the respective observation register */
|
||
regval = CPS_REG_READ(reg);
|
||
/* Compare the error bit values */
|
||
if ((regval & errbitmask) != errorinfobits) {
|
||
*errfoundptr = true;
|
||
}
|
||
return *errfoundptr;
|
||
}
|
||
|
||
static void lpddr4_seterrors(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo, bool * errfoundptr)
|
||
{
|
||
|
||
uint32_t errbitmask = (LPDDR4_BIT_MASK << 0x1U) | LPDDR4_BIT_MASK;
|
||
/* Check PLL observation registers for PLL lock errors */
|
||
|
||
debuginfo->pllerror =
|
||
lpddr4_seterror(&(ctlregbase->LPDDR4__PHY_PLL_OBS_0__REG),
|
||
errbitmask, errfoundptr, PLL_READY);
|
||
if (*errfoundptr == false) {
|
||
debuginfo->pllerror =
|
||
lpddr4_seterror(&(ctlregbase->LPDDR4__PHY_PLL_OBS_1__REG),
|
||
errbitmask, errfoundptr, PLL_READY);
|
||
}
|
||
|
||
/* Check for IO Calibration errors */
|
||
if (*errfoundptr == false) {
|
||
debuginfo->iocaliberror =
|
||
lpddr4_seterror(&
|
||
(ctlregbase->
|
||
LPDDR4__PHY_CAL_RESULT_OBS_0__REG),
|
||
IO_CALIB_DONE, errfoundptr, IO_CALIB_DONE);
|
||
}
|
||
if (*errfoundptr == false) {
|
||
debuginfo->iocaliberror =
|
||
lpddr4_seterror(&
|
||
(ctlregbase->
|
||
LPDDR4__PHY_CAL_RESULT2_OBS_0__REG),
|
||
IO_CALIB_DONE, errfoundptr, IO_CALIB_DONE);
|
||
}
|
||
if (*errfoundptr == false) {
|
||
debuginfo->iocaliberror =
|
||
lpddr4_seterror(&
|
||
(ctlregbase->
|
||
LPDDR4__PHY_CAL_RESULT3_OBS_0__REG),
|
||
IO_CALIB_FIELD, errfoundptr,
|
||
IO_CALIB_STATE);
|
||
}
|
||
}
|
||
|
||
static void lpddr4_setphysnapsettings(lpddr4_ctlregs * ctlregbase,
|
||
const bool errorfound)
|
||
{
|
||
|
||
uint32_t snum = 0U;
|
||
volatile uint32_t *regaddress;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Setting SC_PHY_SNAP_OBS_REGS_x to get a snapshot */
|
||
if (errorfound == false) {
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__SC_PHY_SNAP_OBS_REGS_0__REG));
|
||
/* Iterate through each PHY Data Slice */
|
||
for (snum = 0U; snum < DSLICE_NUM; snum++) {
|
||
regval =
|
||
CPS_FLD_SET(LPDDR4__SC_PHY_SNAP_OBS_REGS_0__FLD,
|
||
CPS_REG_READ(regaddress));
|
||
CPS_REG_WRITE(regaddress, regval);
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress,
|
||
(uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
}
|
||
|
||
static void lpddr4_setphyadrsnapsettings(lpddr4_ctlregs * ctlregbase,
|
||
const bool errorfound)
|
||
{
|
||
|
||
uint32_t snum = 0U;
|
||
volatile uint32_t *regaddress;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Setting SC_PHY ADR_SNAP_OBS_REGS_x to get a snapshot */
|
||
if (errorfound == false) {
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__SC_PHY_ADR_SNAP_OBS_REGS_0__REG));
|
||
/* Iterate through each PHY Address Slice */
|
||
for (snum = 0U; snum < ASLICE_NUM; snum++) {
|
||
regval =
|
||
CPS_FLD_SET(LPDDR4__SC_PHY_ADR_SNAP_OBS_REGS_0__FLD,
|
||
CPS_REG_READ(regaddress));
|
||
CPS_REG_WRITE(regaddress, regval);
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress,
|
||
(uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
}
|
||
|
||
static void lpddr4_setsettings(lpddr4_ctlregs * ctlregbase,
|
||
const bool errorfound)
|
||
{
|
||
|
||
/* Calling functions to enable snap shots of OBS registers */
|
||
lpddr4_setphysnapsettings(ctlregbase, errorfound);
|
||
lpddr4_setphyadrsnapsettings(ctlregbase, errorfound);
|
||
}
|
||
|
||
static void lpddr4_setrxoffseterror(lpddr4_ctlregs * ctlregbase,
|
||
lpddr4_debuginfo * debuginfo,
|
||
bool * errorfound)
|
||
{
|
||
|
||
volatile uint32_t *regaddress;
|
||
uint32_t snum = 0U;
|
||
uint32_t errbitmask = 0U;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Check for rxOffsetError */
|
||
if (*errorfound == false) {
|
||
regaddress =
|
||
(volatile uint32_t
|
||
*)(&(ctlregbase->LPDDR4__PHY_RX_CAL_LOCK_OBS_0__REG));
|
||
errbitmask = (RX_CAL_DONE) | (NIBBLE_MASK);
|
||
/* PHY_RX_CAL_LOCK_OBS_x[4] – RX_CAL_DONE : should be high
|
||
phy_rx_cal_lock_obs_x[3:0] – RX_CAL_STATE : should be zero. */
|
||
for (snum = 0U; snum < DSLICE_NUM; snum++) {
|
||
regval =
|
||
CPS_FLD_READ(LPDDR4__PHY_RX_CAL_LOCK_OBS_0__FLD,
|
||
CPS_REG_READ(regaddress));
|
||
if ((regval & errbitmask) != RX_CAL_DONE) {
|
||
debuginfo->rxoffseterror = true;
|
||
*errorfound = true;
|
||
}
|
||
regaddress =
|
||
lpddr4_addoffset(regaddress,
|
||
(uint32_t) SLICE_WIDTH);
|
||
}
|
||
}
|
||
}
|
||
|
||
uint32_t lpddr4_getdebuginitinfo(const lpddr4_privatedata * pd,
|
||
lpddr4_debuginfo * debuginfo)
|
||
{
|
||
|
||
uint32_t result = 0U;
|
||
bool errorfound = false;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_getdebuginitinfosf(pd, debuginfo);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
lpddr4_seterrors(ctlregbase, debuginfo, &errorfound);
|
||
/* Function to setup Snap for OBS registers */
|
||
lpddr4_setsettings(ctlregbase, errorfound);
|
||
/* Function to check for Rx offset error */
|
||
lpddr4_setrxoffseterror(ctlregbase, debuginfo, &errorfound);
|
||
/* Function Check various levelling errors */
|
||
errorfound = lpddr4_checklvlerrors(pd, debuginfo, errorfound);
|
||
}
|
||
|
||
if (errorfound == true) {
|
||
result = (uint32_t) EPROTO;
|
||
}
|
||
|
||
return result;
|
||
}
|
||
|
||
static void readpdwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_PD_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_PD_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_PD_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_PD_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_PD_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_PD_WAKEUP_F2__REG)));
|
||
}
|
||
}
|
||
|
||
static void readsrshortwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_SHORT_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_SHORT_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_SHORT_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_SHORT_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_SHORT_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_SHORT_WAKEUP_F2__REG)));
|
||
}
|
||
}
|
||
|
||
static void readsrlongwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_LONG_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_LONG_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_LONG_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_WAKEUP_F2__REG)));
|
||
}
|
||
}
|
||
|
||
static void readsrlonggatewakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F2__REG)));
|
||
}
|
||
}
|
||
|
||
static void readsrdpshortwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SRPD_SHORT_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SRPD_SHORT_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SRPD_SHORT_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F2__REG)));
|
||
}
|
||
}
|
||
|
||
static void readsrdplongwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SRPD_LONG_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SRPD_LONG_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__LPI_SRPD_LONG_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F2__REG)));
|
||
}
|
||
}
|
||
|
||
static void readsrdplonggatewakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
uint32_t * cycles)
|
||
{
|
||
|
||
/* Read the appropriate register, based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
*cycles =
|
||
CPS_FLD_READ
|
||
(LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F0__REG)));
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
*cycles =
|
||
CPS_FLD_READ
|
||
(LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F1__REG)));
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
*cycles =
|
||
CPS_FLD_READ
|
||
(LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F2__REG)));
|
||
}
|
||
|
||
}
|
||
|
||
static void lpddr4_readlpiwakeuptime(lpddr4_ctlregs * ctlregbase,
|
||
const lpddr4_lpiwakeupparam *
|
||
lpiwakeupparam,
|
||
const lpddr4_ctlfspnum * fspnum,
|
||
uint32_t * cycles)
|
||
{
|
||
|
||
/* Iterate through each of the Wake up parameter type */
|
||
if (*lpiwakeupparam == LPDDR4_LPI_PD_WAKEUP_FN) {
|
||
/* Calling appropriate function for register read */
|
||
readpdwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SR_SHORT_WAKEUP_FN) {
|
||
readsrshortwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SR_LONG_WAKEUP_FN) {
|
||
readsrlongwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SR_LONG_MCCLK_GATE_WAKEUP_FN) {
|
||
readsrlonggatewakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SRPD_SHORT_WAKEUP_FN) {
|
||
readsrdpshortwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SRPD_LONG_WAKEUP_FN) {
|
||
readsrdplongwakeup(fspnum, ctlregbase, cycles);
|
||
} else {
|
||
/* Default function (sanity function already confirmed the variable value) */
|
||
readsrdplonggatewakeup(fspnum, ctlregbase, cycles);
|
||
}
|
||
}
|
||
|
||
uint32_t lpddr4_getlpiwakeuptime(const lpddr4_privatedata * pd,
|
||
const lpddr4_lpiwakeupparam * lpiwakeupparam,
|
||
const lpddr4_ctlfspnum * fspnum,
|
||
uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t result = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_getlpiwakeuptimesf(pd, lpiwakeupparam, fspnum, cycles);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
lpddr4_readlpiwakeuptime(ctlregbase, lpiwakeupparam, fspnum,
|
||
cycles);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
static void writepdwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase, const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_PD_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_PD_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__LPI_PD_WAKEUP_F0__REG),
|
||
regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_PD_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_PD_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__LPI_PD_WAKEUP_F1__REG),
|
||
regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_PD_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_PD_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__LPI_PD_WAKEUP_F2__REG),
|
||
regval);
|
||
}
|
||
}
|
||
|
||
static void writesrshortwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_SHORT_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_SHORT_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->LPDDR4__LPI_SR_SHORT_WAKEUP_F0__REG),
|
||
regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_SHORT_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_SHORT_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->LPDDR4__LPI_SR_SHORT_WAKEUP_F1__REG),
|
||
regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_SHORT_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_SHORT_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->LPDDR4__LPI_SR_SHORT_WAKEUP_F2__REG),
|
||
regval);
|
||
}
|
||
}
|
||
|
||
static void writesrlongwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_LONG_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__LPI_SR_LONG_WAKEUP_F0__REG),
|
||
regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_LONG_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__LPI_SR_LONG_WAKEUP_F1__REG),
|
||
regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_LONG_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__LPI_SR_LONG_WAKEUP_F2__REG),
|
||
regval);
|
||
}
|
||
}
|
||
|
||
static void writesrlonggatewakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F0__REG),
|
||
regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F1__REG),
|
||
regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SR_LONG_MCCLK_GATE_WAKEUP_F2__REG),
|
||
regval);
|
||
}
|
||
}
|
||
|
||
static void writesrdpshortwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SRPD_SHORT_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F0__REG), regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SRPD_SHORT_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F1__REG), regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SRPD_SHORT_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_SHORT_WAKEUP_F2__REG), regval);
|
||
}
|
||
}
|
||
|
||
static void writesrdplongwakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SRPD_LONG_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F0__REG), regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SRPD_LONG_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F1__REG), regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__LPI_SRPD_LONG_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_WAKEUP_F2__REG), regval);
|
||
}
|
||
}
|
||
|
||
static void writesrdplonggatewakeup(const lpddr4_ctlfspnum * fspnum,
|
||
lpddr4_ctlregs * ctlregbase,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
uint32_t regval = 0U;
|
||
/* Write to appropriate register ,based on user given frequency. */
|
||
if (*fspnum == LPDDR4_FSP_0) {
|
||
regval =
|
||
CPS_FLD_WRITE
|
||
(LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F0__REG),
|
||
regval);
|
||
} else if (*fspnum == LPDDR4_FSP_1) {
|
||
regval =
|
||
CPS_FLD_WRITE
|
||
(LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F1__REG),
|
||
regval);
|
||
} else {
|
||
/* Default register (sanity function already confirmed the variable value) */
|
||
regval =
|
||
CPS_FLD_WRITE
|
||
(LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&
|
||
(ctlregbase->
|
||
LPDDR4__LPI_SRPD_LONG_MCCLK_GATE_WAKEUP_F2__REG),
|
||
regval);
|
||
}
|
||
}
|
||
|
||
static void lpddr4_writelpiwakeuptime(lpddr4_ctlregs * ctlregbase,
|
||
const lpddr4_lpiwakeupparam *
|
||
lpiwakeupparam,
|
||
const lpddr4_ctlfspnum * fspnum,
|
||
const uint32_t * cycles)
|
||
{
|
||
|
||
/* Iterate through each of the Wake up parameter type */
|
||
if (*lpiwakeupparam == LPDDR4_LPI_PD_WAKEUP_FN) {
|
||
/* Calling appropriate function for register write */
|
||
writepdwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SR_SHORT_WAKEUP_FN) {
|
||
writesrshortwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SR_LONG_WAKEUP_FN) {
|
||
writesrlongwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SR_LONG_MCCLK_GATE_WAKEUP_FN) {
|
||
writesrlonggatewakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SRPD_SHORT_WAKEUP_FN) {
|
||
writesrdpshortwakeup(fspnum, ctlregbase, cycles);
|
||
} else if (*lpiwakeupparam == LPDDR4_LPI_SRPD_LONG_WAKEUP_FN) {
|
||
writesrdplongwakeup(fspnum, ctlregbase, cycles);
|
||
} else {
|
||
/* Default function (sanity function already confirmed the variable value) */
|
||
writesrdplonggatewakeup(fspnum, ctlregbase, cycles);
|
||
}
|
||
}
|
||
|
||
uint32_t lpddr4_setlpiwakeuptime(const lpddr4_privatedata * pd,
|
||
const lpddr4_lpiwakeupparam * lpiwakeupparam,
|
||
const lpddr4_ctlfspnum * fspnum,
|
||
const uint32_t * cycles)
|
||
{
|
||
uint32_t result = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_setlpiwakeuptimesf(pd, lpiwakeupparam, fspnum, cycles);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
/* Return if the user given value is higher than the field width */
|
||
if (*cycles > NIBBLE_MASK) {
|
||
result = EINVAL;
|
||
}
|
||
}
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
lpddr4_writelpiwakeuptime(ctlregbase, lpiwakeupparam, fspnum,
|
||
cycles);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_geteccenable(const lpddr4_privatedata * pd,
|
||
lpddr4_eccenable * eccparam)
|
||
{
|
||
uint32_t result = 0U;
|
||
uint32_t fldval = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_geteccenablesf(pd, eccparam);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Reading the ECC_Enable field from the register. */
|
||
fldval =
|
||
CPS_FLD_READ(LPDDR4__ECC_ENABLE__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__ECC_ENABLE__REG)));
|
||
switch (fldval) {
|
||
case 3:
|
||
*eccparam = LPDDR4_ECC_ERR_DETECT_CORRECT;
|
||
break;
|
||
case 2:
|
||
*eccparam = LPDDR4_ECC_ERR_DETECT;
|
||
break;
|
||
case 1:
|
||
*eccparam = LPDDR4_ECC_ENABLED;
|
||
break;
|
||
default:
|
||
/* Default ECC (Sanity function already confirmed the value to be in expected range.) */
|
||
*eccparam = LPDDR4_ECC_DISABLED;
|
||
break;
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_seteccenable(const lpddr4_privatedata * pd,
|
||
const lpddr4_eccenable * eccparam)
|
||
{
|
||
|
||
uint32_t result = 0U;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_seteccenablesf(pd, eccparam);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Updating the ECC_Enable field based on the user given value. */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__ECC_ENABLE__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__ECC_ENABLE__REG)),
|
||
*eccparam);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__ECC_ENABLE__REG), regval);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_getreducmode(const lpddr4_privatedata * pd,
|
||
lpddr4_reducmode * mode)
|
||
{
|
||
uint32_t result = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_getreducmodesf(pd, mode);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Read the value of reduc parameter. */
|
||
if (CPS_FLD_READ
|
||
(LPDDR4__REDUC__FLD,
|
||
CPS_REG_READ(&(ctlregbase->LPDDR4__REDUC__REG))) == 0U) {
|
||
*mode = LPDDR4_REDUC_ON;
|
||
} else {
|
||
*mode = LPDDR4_REDUC_OFF;
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_setreducmode(const lpddr4_privatedata * pd,
|
||
const lpddr4_reducmode * mode)
|
||
{
|
||
uint32_t result = 0U;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_setreducmodesf(pd, mode);
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Setting to enable Half data path. */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__REDUC__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__REDUC__REG)), *mode);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__REDUC__REG), regval);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_getdbireadmode(const lpddr4_privatedata * pd, bool * on_off)
|
||
{
|
||
|
||
uint32_t result = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_getdbireadmodesf(pd, on_off);
|
||
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Reading the field value from the register. */
|
||
if (CPS_FLD_READ
|
||
(LPDDR4__RD_DBI_EN__FLD,
|
||
CPS_REG_READ(&(ctlregbase->LPDDR4__RD_DBI_EN__REG))) ==
|
||
0U) {
|
||
*on_off = false;
|
||
} else {
|
||
*on_off = true;
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_getdbiwritemode(const lpddr4_privatedata * pd, bool * on_off)
|
||
{
|
||
|
||
uint32_t result = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_getdbireadmodesf(pd, on_off);
|
||
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Reading the field value from the register. */
|
||
if (CPS_FLD_READ
|
||
(LPDDR4__WR_DBI_EN__FLD,
|
||
CPS_REG_READ(&(ctlregbase->LPDDR4__WR_DBI_EN__REG))) ==
|
||
0U) {
|
||
*on_off = false;
|
||
} else {
|
||
*on_off = true;
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_setdbimode(const lpddr4_privatedata * pd,
|
||
const lpddr4_dbimode * mode)
|
||
{
|
||
|
||
uint32_t result = 0U;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_setdbimodesf(pd, mode);
|
||
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Updating the appropriate field value based on the user given mode */
|
||
if (*mode == LPDDR4_DBI_RD_ON) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__RD_DBI_EN__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__RD_DBI_EN__REG)),
|
||
1U);
|
||
} else if (*mode == LPDDR4_DBI_RD_OFF) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__RD_DBI_EN__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__RD_DBI_EN__REG)),
|
||
0U);
|
||
} else if (*mode == LPDDR4_DBI_WR_ON) {
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__WR_DBI_EN__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__WR_DBI_EN__REG)),
|
||
1U);
|
||
} else {
|
||
/* Default field (Sanity function already confirmed the value to be in expected range.) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__WR_DBI_EN__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__WR_DBI_EN__REG)),
|
||
0U);
|
||
}
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__RD_DBI_EN__REG), regval);
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_getrefreshrate(const lpddr4_privatedata * pd,
|
||
const lpddr4_ctlfspnum * fspnum,
|
||
uint32_t * cycles)
|
||
{
|
||
uint32_t result = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_getrefreshratesf(pd, fspnum, cycles);
|
||
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Selecting the appropriate register for the user requested Frequency */
|
||
switch (*fspnum) {
|
||
case LPDDR4_FSP_2:
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__TREF_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_F2__REG)));
|
||
break;
|
||
case LPDDR4_FSP_1:
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__TREF_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_F1__REG)));
|
||
break;
|
||
default:
|
||
/* FSP_0 is considered as the default (sanity check already confirmed it as valid FSP) */
|
||
*cycles =
|
||
CPS_FLD_READ(LPDDR4__TREF_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_F0__REG)));
|
||
break;
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_setrefreshrate(const lpddr4_privatedata * pd,
|
||
const lpddr4_ctlfspnum * fspnum,
|
||
const uint32_t * cycles)
|
||
{
|
||
uint32_t result = 0U;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_setrefreshratesf(pd, fspnum, cycles);
|
||
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
|
||
/* Selecting the appropriate register for the user requested Frequency */
|
||
switch (*fspnum) {
|
||
case LPDDR4_FSP_2:
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__TREF_F2__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_F2__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__TREF_F2__REG),
|
||
regval);
|
||
break;
|
||
case LPDDR4_FSP_1:
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__TREF_F1__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_F1__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__TREF_F1__REG),
|
||
regval);
|
||
break;
|
||
default:
|
||
/* FSP_0 is considered as the default (sanity check already confirmed it as valid FSP) */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__TREF_F0__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_F0__REG)),
|
||
*cycles);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__TREF_F0__REG),
|
||
regval);
|
||
break;
|
||
}
|
||
}
|
||
return result;
|
||
}
|
||
|
||
uint32_t lpddr4_refreshperchipselect(const lpddr4_privatedata * pd,
|
||
const uint32_t trefinterval)
|
||
{
|
||
uint32_t result = 0U;
|
||
uint32_t regval = 0U;
|
||
|
||
/* Calling Sanity Function to verify the input variables */
|
||
result = lpddr4_refreshperchipselectsf(pd);
|
||
|
||
if (result == (uint32_t) CDN_EOK) {
|
||
lpddr4_ctlregs *ctlregbase = (lpddr4_ctlregs *) pd->ctlbase;
|
||
/* Setting tref_interval parameter to enable/disable Refresh per chip select. */
|
||
regval =
|
||
CPS_FLD_WRITE(LPDDR4__TREF_INTERVAL__FLD,
|
||
CPS_REG_READ(&
|
||
(ctlregbase->
|
||
LPDDR4__TREF_INTERVAL__REG)),
|
||
trefinterval);
|
||
CPS_REG_WRITE(&(ctlregbase->LPDDR4__TREF_INTERVAL__REG),
|
||
regval);
|
||
}
|
||
return result;
|
||
}
|